The present invention discloses an electromagnetic wave spatial analysis method based on multi-level dipole group modeling. The electromagnetic wave spatial analysis method includes the following steps: S1, obtaining a magnetic dipole group according to three-phase loops of power grids of various different voltage levels, and obtaining spatial coordinates of the magnetic dipole group according to the longitudes and latitudes as well as the altitudes of the power grids of various voltage levels; S2, calculating the loop length of each three-phase magnetic dipole according to the spatial coordinates of the magnetic dipole group, and obtaining a multi-level magnetic dipole group according to the loop lengths; S3, obtaining the current corresponding to the voltage on power transmission loops in the power grids of various voltage levels at different levels according to the installed capacities of the power grids of various voltage levels in different countries; S4, building a multi-level dipole model according to the multi-level magnetic dipole group and the current; and S5, solving the multi-level dipole model to obtain spatial power frequency electromagnetic wave distribution. The altitude factor of grid distribution is added in the present invention, and the power grids are divided into multiple levels for modeling analysis respectively, thereby increasing the analytical accuracy of power frequency electromagnetic waves.
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2. The electromagnetic wave spatial analysis method according to claim 1, wherein in step S1, by directly performing statistics to obtain the longitudes and latitudes of grid nodes, a curved surface model is constructed according to the curvature of the earth, and the spatial coordinates of the magnetic dipoles are calculated according to the longitudes and latitudes.
3. The electromagnetic wave spatial analysis method according to claim 1, wherein in step S2, the loop length of each three-phase magnetic dipole is obtained by taking into account the altitude factor of the power transmission loops.
4. The electromagnetic wave spatial analysis method according to claim 3, wherein in step S2, the multi-level magnetic dipole group is established by making the power grid of each voltage level corresponding to any one of the loop lengths λ, λ/2, λ/4, λ/8, and λ/10 equivalent to a magnetic dipole, and making the multiple power transmission loops with the sum of lengths satisfying the length conditions described above equivalent to the antenna arrays implementing the magnetic dipole functions.
5. The electromagnetic wave spatial analysis method according to claim 1, wherein in step S4, the multi-level dipole model comprises: an ionized layer, a land-ocean-seabed layer, and an air layer.
6. The electromagnetic wave spatial analysis method according to claim 5, wherein a multi-level medium model is established taking into account the absorption and refraction of power frequency electromagnetic waves by the ionized layer and the factor that the power frequency electromagnetic waves reach a seawater layer through the land and the seabed; and a simulated multi-level dipole group model is built by carrying out modeling on a high-voltage power transmission network by the voltage levels respectively.
7. The electromagnetic wave spatial analysis method according to claim 1, wherein step S5 specifically comprises: calculating the electromagnetic wave transmission characteristic and the spatial distribution of each power transmission loop of which the voltage level is equivalent to a dipole or the power transmission loops capable of implementing the dipole functions, and carrying out vector superposition on power frequency electromagnetic waves generated by the power transmission loops with multiple voltage levels in a space.
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December 30, 2022
August 6, 2024
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